17.13: *Estimate of Orbital Angular Momentum of an Electron in an Atom

17.14: *Magnetic Field of a Solenoid

17: Questions (8)

17: Computational Problems

Chapter 18: Electric Field and Circuits

18.1: A Circuit is Not in Equilibrium

18.2: Current in Different Parts of a Circuit (11)

18.3: Electric Field and Current (9)

18.4: What Charges Make the Electric Field Inside the Wires?

18.5: Surface Charge Distributions

18.6: Connecting a Circuit: The Initial Transient

18.7: Feedback

18.8: Surface Charge and Resistors

18.9: Energy in a Circuit

18.10: Applications of the Theory (20)

18.11: Detecting Surface Charge

18.12: *Computational Model of a Circuit

18: Questions (2)

18: Computational Problems

Chapter 19: Circuit Elements

19.1: Capacitors (16)

19.2: Resistors (20)

19.3: Conventional Symbols and Terms

19.4: Work and Power in a Circuit (6)

19.5: Batteries (4)

19.6: Ammeters, Voltmeters, and Ohmmeters (3)

19.7: Quantitative Analysis of an RC Circuit (4)

19.8: Reflection: The Macro–Micro Connection

19.9: *What Are AC and DC?

19.10: *Electrons in Metals

19.11: *A Complicated Resistive Circuit (3)

19: Questions

19: Computational Problems

Chapter 20: Magnetic Force

20.1: Magnetic Force on a Moving Charge (15)

20.2: Magnetic Force on a Current-Carrying Wire (9)

20.3: Combining Electric and Magnetic Forces (14)

20.4: The Hall Effect (8)

20.5: Motional Emf (11)

20.6: Magnetic Force in a Moving Reference Frame (1)

20.7: Magnetic Torque (2)

20.8: Potential Energy for a Magnetic Dipole (2)

20.9: Motors and Generators (1)

20.10: *Case Study: Sparks in Air (8)

20.11: *Relativistic Field Transformations

20: Questions (3)

20: Computational Problems

Chapter 21: Patterns of Field in Space

21.1: Patterns of Electric Field: Gauss's Law

21.2: Definition of "Electric Flux" (3)

21.3: Gauss's Law (11)

21.4: Reasoning from Gauss's Law (6)

21.5: Gauss's Law for Magnetism

21.6: Patterns of Magnetic Field: Ampere's Law (8)

21.7: Maxwell's Equations

21.8: Semiconductor Devices

21.9: *The Differential Form of Gauss's Law (1)

21.10: *The Differential Form of Ampere's Law

21: Questions (1)

21: Computational Problems

Chapter 22: Faraday's Law

22.1: Curly Electric Fields (5)

22.2: Faraday's Law (27)

22.3: Faraday's Law and Motional Emf (1)

22.4: Maxwell's Equations

22.5: Superconductors (1)

22.6: Inductance (3)

22.7: *Inductor Circuits (3)

22.8: *Some Peculiar Circuits

22.9: *The Differential Form of Faraday's Law

22.10: *Lenz's Rule

22: Questions (1)

22: Computational Problems

Chapter 23: Electromagnetic Radiation

23.1: Maxwell's Equations (1)

23.2: Fields Traveling Through Space (4)

23.3: Accelerated Charges Produce Radiation (10)

23.4: Sinusoidal Electromagnetic Radiation (4)

23.5: Energy and Momentum in Radiation (3)

23.6: Effects of Radiation on Matter (2)

23.7: Light Propagation Through a Medium (1)

23.8: Refraction: Bending of Light (5)

23.9: Lenses

23.10: Image Formation (7)

23.11: *The Field of an Accelerated Charge

23.12: *Differential Form of Maxwell's Equations

23: Questions (3)

23: Computational Problems

Chapter S1: Gases and Heat Engines

S1.1: Gases, Solids, and Liquids

S1.2: Gas Leaks Through a Hole (6)

S1.3: Mean Free Path

S1.4: Pressure and Temperature (2)

S1.5: Energy Transfers (6)

S1.6: Fundamental Limitations on Efficiency (2)

S1.7: A Maximally Efficient Process (5)

S1.8: *Why Don't We Attain the Theoretical Efficiency?

S1.9: *Application: A Random Walk (1)

S1: Questions (1)

Chapter S2: Semiconductor Devices

S2.1: Semiconductor Devices (1)

S2: Questions

Chapter S3: Waves

S3.1: Wave Phenomena (8)

S3.2: Multisource Interference: Diffraction (6)

S3.3: Angular Resolution (8)

S3.4: Mechanical Waves (9)

S3.5: Standing Waves (3)

S3.6: Wave and Particle Models of Light (4)

S3.7: *Fourier Analysis

S3.8: *Derivation: Two Slits are Like Two Sources

S3.9: *The Wave Equation for Light

S3: Questions

Matter and Interactions 4th edition, by Chabay and Sherwood, offers a modern curriculum for calculus-based introductory physics. It presents physics the way practicing physicists view their discipline and integrates 20th century physics and computational physics. The WebAssign content for this textbook was originally designed by the textbook authors to take full advantage of the unique capabilities of WebAssign.

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